Vapor circulation in hydrocarbon conversion processes

ABSTRACT

A hydrocarbon conversion process wherein a fractionation column overhead vapor stream is circulated through a portion of the process, such as through a purification zone or hydrocarbon recovery zone. Part of the motive force for this vapor circulation is derived from depressurizing the vaporous phase of a mixed-phase reaction zone effluent through an ejector which draws a suction on the overhead receiver of the fractionation column.

CROSS-REFERENCE TO RELATED APPLICATION

This application is a Continuation-In-Part of my prior application Ser. No. 801,984 filed May 31, 1977, now U.S. Pat. No. 4,079,093. The teachings of my prior application are incorporated herein by reference.

FIELD OF THE INVENTION

The invention relates to hydrocarbon conversion processes in general, including processes for the alkylation of aromatic hydrocarbons by the introduction of an acyclic side chain, and the hydrodealkylation, hydrocdesulfurization and reforming of petroleum streams. The invention also relates to the separation of a mixed-phase reaction zone effluent stream produced in such a process and to circulation of process vapor streams through the use of fluid jet ejectors.

PRIOR ART

The wide commercial utilization of hydrocarbon conversion processes has resulted in much developmental effort and a very high state of the art. Specific processes, such as the alkylation of aromatic hydrocarbons, are therefore well developed and are performed using a wide variety of catalysts and equipment configurations. The alkylation of aromatic hydrocarbons using a volatile catalyst promoter is described in U.S. Pat. Nos. 3,894,090 (Cl. 260-671); 3,631,122 and 2,971,992. The latter reference also shows the passage of the alkylation zone effluent into a vapor-liquid separator, with a vapor stream comprising boron trifluoride, unreactive gases and the aromatic hydrocarbon being removed from the separator and passed into a countercurrent gas-liquid absorption zone. A stream of polyalkylated aromatic hydrocarbons is fed to the top of this zone to effect the recovery of the boron trifluoride and aromatic hydrocarbon. The unreactive gases are vented from the top of this zone.

The preferred catalyst system is also described in U.S. Pat. No. 3,126,421 (Cl. 260-671). In the alkylation process presented by this reference the effluents of an alkylation zone and a transalkylation zone are combined and passed into a flash drum. The liquid removed from the flash drum is passed into a benzene column. The vapor removed from the flash drum is cooled and passed into a vapor-liquid separator. The vapor removed from this separator is passed into the absorber of a boron trifluoride recovery zone comprising an absorber and a stripper. The enriched boron trifluoride produced in this zone is recirculated to the alkylation and transalkylation zones. This same reference also shows the removal of a boron trifluoride-containing overhead vapor from the benzene column. This overhead vapor stream is, however, recycled to the alkylation zone and not passed into a reaction zone vapor-liquid separator as in the present invention. Another feature illustrated by this reference is the production of a benzene recycle stream from the overhead vapors removed from the benzene column.

Previously cited U.S. Pat. No. 3,894,090 shows a benzene recycle stream withdrawn from the benzene column as a sidecut stream. This reference also describes the passage of boron trifluoride into the benzene column to prevent the precipitation of relatively non-volatile hydrates of boron oxide commonly referred to as borates.

The use of a jet ejector to pull a vacuum on a fractionation column is a well established practice. Very often the motive stream used is high pressure steam which is subsequently condensed.

SUMMARY OF THE INVENTION

The invention provides a hydrocarbon conversion process wherein part of the motive force required for the circulation of a fractionation column off-gas stream comprising a volatile chemical, such as hydrogen or boron trifluoride, is provided by depressurizing the vapor phase portion of the effluent of the reaction zone through an ejector. This ejector is used to pump the overhead vapors of the fractionation column into a vapor-liquid separation zone into which the alkylation zone effluent is also charged. The vapors separated in this zone are then passed into a vapor purification zone. The invention thereby provides a hydrocarbon conversion process requiring less compressor capacity and having lower operating costs than the prior art, which, for instance, mechanically compressed the overhead vapors of the fractionation column and passed them into the vapor purification zone.

The invention finds specific application to the processes of benzene alkylation, alkylaromatic hydrocarbon hydrodealkylation and hydrodesulfurization. The invention may be broadly characterized as a hydrocarbon conversion process which comprises the steps of passing a mixed-phase reaction zone effluent stream into a first vapor-liquid separation zone and forming therein a first liquid hydrocarbon stream comprising a hydrocarbon having six or more carbon atoms per molecule and a first vapor stream comprising a volatile chemical chosen from the group consisting of methane, ethane, ethylene, propane, hydrogen, water, hydrogen sulfide, boron trifluoride, carbon tetrachloride, hydrogen fluoride and hydrogen bromide; passing at least a portion of the first vapor stream through an ejector as a motive stream utilized to pump a second vapor stream comprising the volatile chemical chosen from the group consisting of methane, ethane, ethylene, propane, hydrogen, water, hydrogen sulfide, boron trifluoride, carbon tetrachloride, hydrogen fluoride and hydrogen bromide and thereby forming an ejector effluent vapor stream; passing the ejector effluent vapor stream into a second vapor-liquid separation zone having a lower pressure than the first vapor-liquid separation zone; passing the first liquid hydrocarbon stream into the second vapor-liquid separation zone; passing a second liquid hydrocarbon stream comprising the hydrocarbon having six or more carbon atoms per molecule from the second vapor-liquid separation zone to a fractionation zone having a lower pressure than the second vapor-liquid separation zone; withdrawing from the fractionation zone a net overhead vapor stream comprising the volatile chemical chosen from the group consisting of methane, ethane, ethylene, propane, hydrogen, water, hydrogen sulfide, boron trifluoride, carbon tetrachloride, hydrogen fluoride and hydrogen bromide and passing the net overhead vapor stream into the ejector as the second vapor stream; withdrawing from the second vapor-liquid separation zone a third vapor stream comprising the volatile chemical chosen from the group consisting of methane, ethane, ethylene, propane, hydrogen, water, hydrogen sulfide, boron trifluoride, carbon tetrachloride, hydrogen fluoride and hydrogen bromide, and passing the third vapor stream into a vapor purification zone which effects the removal of an impurity from the third vapor stream to produce a fourth vapor stream having a higher concentration of the volatile chemical chosen from the group consisting of methane, ethane, ethylene, propane, hydrogen, water, hydrogen sulfide, boron trifluoride, carbon tetrachloride, hydrogen fluoride and hydrogen bromide than the third vapor stream; and, withdrawing a fractionation product stream comprising the hydrocarbon having six or more carbon atoms per molecule from the fractionation zone.

DESCRIPTION OF THE DRAWINGS

The Drawing illustrates the preferred embodiment of the invention. For clarity and simplicity various subsystems and apparatus associated with the operation of the process have not been shown. These items include flow and pressure control valves, pumps, temperature and pressure monitoring systems, reactor and fractionator internals, etc., which may be of customary design. This representation of the preferred embodiment is not intended to preclude from the scope of the invention those other embodiments set out herein or which are the result of reasonable and normal modification of these embodiments.

Referring now to the drawing, a feed stream comprising ethylene enters the process through line 1 and is admixed with a feed stream comprising benzene which enters through line 2. The resultant admixture is carried by line 1 to the junction with line 3, where it is commingled with a recycle vapor stream comprising boron trifluoride. The feed material continues through line 4 and is admixed with a portion of a recycle benzene stream carried by line 48. Line 4 carries the resultant mixture of benzene, ethylene and boron trifluoride to the junction with line 55 where it is combined with a recycled portion of the alkylation zone effluent, which has been cooled by a means not shown. This produces a combined alkylation zone feed stream which is passed into the alkylation reactor 6 through line 5. The effluent of the alkylation reactor is removed in line 7 and divided into the portion which is recycled through line 55 and a second portion which is passed through line 8 into a vapor-liquid separator 9.

The net effluent stream of the alkylation reactor is separated into a vapor stream comprising boron trifluoride and possibly other non-reactive gases, such as nitrogen and paraffins which were contained in the ethylene feed stream, and which is removed in line 34, and a liquid stream comprising benzene, the product ethylbenzene and polyalkylated benzenes. The liquid stream is removed in line 11 at a rate controlled by valve 10 which preferably is operated by a level control means sensing the liquid level in the separator 9. The liquid stream in line 11 is combined with the effluent stream of a transalkylation reactor 12 which is carried by line 13. The effluent stream of the transalkylation reactor comprises benzene, ethylbenzene, polyalkylated benzenes and boron trifluoride. Line 14 carries the resultant admixture of these two streams into a separating vessel 15. A liquid phase stream is removed from this separating vessel in line 16. A vapor stream comprising boron trifluoride is removed from the separating vessel 15 in line 18 and passed through a cooler 19. This results in the condensation of readily condensible hydrocarbons, such as benzene and ethylbenzene, which are collected as a liquid phase in a second separating vessel 20. The uncondensed vapors, including boron trifluoride are removed from the second vessel in line 21, and the condensate is removed in line 17. The condensate is then combined with the liquid stream from the first separating vessel and passed into line 24.

Material in line 24 is passed into a benzene column 25. Also passed into this column is a stream of vaporous boron trifluoride from line 50. The boron trifluoride and various relatively volatile hydrocarbons rise through the benzene column and are removed as an overhead vapor stream in line 27. The overhead vapor stream is passed through overhead condenser 28 which causes the condensation of benzene and other hydrocarbons having similar or higher boiling points. The overhead of the benzene column is then passed into an overhead receiver 29 and separated into a liquid phase reflux stream removed in line 30 and a vapor stream removed in line 31. This vapor stream comprises boron trifluoride and such relatively non-condensible light gases as nitrogen, methane or ethane which were contained in the ethylene feed stream. A stream of makeup boron trifluoride is passed into the process through line 32. The resultant boron trifluoride enriched vapor stream is caused to pass through line 33 by the suction generated in an ejector 38. This suction is created through the depressurization of the relatively high pressure vaporous portion of the alkylation zone effluent passing through line 34. At least a portion of the vaporous effluent is used as the motive stream passed into the ejector in line 37. A second portion of the vaporous effluent may be bypassed around the ejector through line 35 at a rate controlled by valve 36. The effluent of the ejector is admixed with any vaporous alkylation zone effluent which has been bypassed around the ejector and is then passed into the first settling vessel 15 through line 40. In this manner the relatively high pressure of the alkylation zone is utilized to remove the net uncondensed overhead vapors of the benzene column and to circulate these vapors into a first receiving vessel. From the first receiving vessel these vapors flows through line 18 and 21 in admixture with the vapors released from the liquid passing through line 14.

A vapor stream in line 21 is passed into a promoter recovery zone 22. Preferably, this zone comprises a countercurrent absorption column and a stripping column. The operation of this preferred recovery zone configuration is described in greater detail herein. An off-gas stream comprising such impurities as nitrogen, methane and ethane is removed from the process in line 56. A purified stream of boron trifluoride vapors is removed in line 23 for recycling within the process. A first portion of this purified stream is passed into the bottom of the benzene column through line 50. The remaining portion passes through line 51 and is pressurized in a compressor 54. This pressurized portion is then divided between the boron trifluoride stream passed to the alkylation zone through line 3 and the boron trifluoride stream passed to the transalkylation zone through line 52

A sidecut stream comprising benzene is removed from the benzene column in line 26 and passed through alumina treater 46. This fractionation product stream is then recycled through line 47 to provide the recycle benzene which is passed into the alkylation zone via line 48 and into the transalkylation zone via line 49. A net bottoms stream is removed from the benzene column in line 41 and passed into a fractionation zone 42. Preferably, this fractionation zone comprises two fractionation columns as described in greater detail herein. A net overhead product stream of substantially pure ethylbenzene is removed from the first fractionation column and forms the product stream removed in line 44. Preferably, a second fractionation column separates from the remaining hydrocarbons a relatively small by-product stream removed in line 43 and which comprises various high boiling aromatic hydrocarbons and polymers. This leaves the intermediate hydrocarbons including various bi- and tri-alkylated ethylbenzenes which are concentrated into a recycle stream removed in line 45. This recycle stream is combined with the boron trifluoride from line 52 and a recycle benzene stream from line 49 and passed into the transalkylation reactor through line 53.

DETAILED DESCRIPTION

The subject invention may be applied to a wide variety of hydrocarbon conversion processes which satisfy a set of criteria based on process conditions and methods and independent of the reaction performed in the process. This set of criteria includes the existence of a mixed-phase reaction zone effluent stream. The reaction zone effluent may be a vapor-phase stream as it emerges from the reaction zone and subjected to a subsequent cooling operation which causes the partial condensation of reaction zone effluent stream before it is passed into the first vapor-liquid separation zone. This will commonly be the situation in most processes for the hydrocracking or hydrotreating of light vaporizable petroleum stocks. In other processes, such as aromatic alkylation processes for the production of cumene or gasoline blending components which utilize an SPA catalyst, the reaction zone effluent is normally a mixed-phase stream as it emerges from the reaction zone.

The criteria which determine the applicability of the subject invention to a particular process also include two pressure differentials. These inherent characteristics include a substantially greater pressure in the reaction zone and in the first separation zone than in the second vapor-liquid separation zone. This is necessary to allow the vapor phase motive stream to be depressurized through the ejector into the second separation zone. It is also necessary that the pressure in the fractionation column be less than that in the second vapor-liquid separation zone and in the vapor purification zone since an objective of the invention is to transfer the net overhead vapors of the fractionation column to a purification zone having a higher pressure than the fractionation column.

The alkylation of aromatic hydrocarbons finds utility in several industrial processes. It is performed for instance to effect the production of ethylbenzene from benzene and ethylene, with much of the product ethylbenzene being subsequently dehydrogenated to produce styrene. In a similar manner, isopropylbenzene or cumene may be formed by the reaction of propylene and benzene. Cumene is used in the synthesis of phenol, acetone, alphamethylstyrene and acetophenone. These cumene-derived chemicals are intermediates in the production of resins for plastics including nylon. Other aromatic hydrocarbons are possible feedstocks for use in the subject invention. These include alkyl-substituted aromatics such as toluene, phenols and polycyclic aromatics. However, as the preferred embodiment of the invention concerns the alkylation of benzene and the prior art examples are often also based on the use of this feedstock, the invention will be described mainly in terms of benzene alkylation. This is not intended to in any way exclude other aromatic feedstocks from use in the invention.

Furthermore, the invention is one of general application within the broad field of hydrocarbon conversion processes. It may be applied to other specific reactions including reforming, dehydrogenation, isomerization of paraffins and aromatics, hydrodecyclization, hydroformylation, hydrodesulfurization, coal gasification and liquefaction, hydrocracking, esterification, methanation, hydrogenation and the alkylation of paraffinic or olefinic hydrocarbons. Any of these reactions could be performed in the reaction zone. In a similar manner the catalyst promoter recovery zone could be replaced by other types of purification operations, including gas concentration units. The basic concept is therefore a hydrocarbon conversion process in which a relatively high pressure mixed-phase reaction zone effluent stream is separated into liquid and vapor phases, the vapor phase is depressurized through an ejector to thereby increase the pressure of a low pressure vapor stream and to pump the low pressure stream, or a portion thereof, into an intermediate pressure zone in admixture with at least some of the reaction zone effluent vapor.

The preferred catalyst system for use in the alkylation zone, and in the transalkylation zone if one is present, is one which utilizes a catalyst promoter which is vaporous at standard conditions of temperature and pressure. This catalyst promoter is preferably a halogen-containing compound chosen from the group consisting of boron trifluoride, boron trichloride, boron tribromide, hydrogen chloride, carbon tetrachloride, hydrogen fluoride, hydrogen bromide, ammonium fluoride, ammonium chloride, ammonium bromide and ammonium iodide. More preferably the catalyst promoter is a boron halide, with boron trifluoride being especially preferred.

The preferred catalyst system is described in U.S. Pat. Nos. 3,126,421 (Cl. 260- 671); 3,631,122 and 3,894,090. The reaction zones contain a boron halide-promoted catalyst utilizing a solid carrier and maintained in an anhydrous condition. Preferably the boron halide is boron trifluoride and the carrier is an inorganic oxide. The carrier may be selected from among many inorganic oxides including alumina, silica, boria, oxides of phosphorus, titanium dioxide, zirconium dioxide, chromia, etc., and various naturally occurring inorganic oxides of various states of purity, such as clay or diatomaceous earth. Of the above-mentioned inorganic oxides, the gamma and theta forms of alumina are most readily modified by boron trifluoride, and the use of one or both of these materials is preferred. The reaction zones may also or alternatively contain a bed of a crystalline aluminosilicate zeolite.

Modification of the carrier may be carried out prior to or simultaneously with the initial passage of the reactants over the carrier. This modification is accomplished by the passage of a boron trifluoride-containing gas stream over a bed of the carrier material maintained at an elevated temperature of from about 300° F. to about 500° F. To maintain the catalyst in an active state during operation, boron trifluoride is recirculated to each reaction zone at the relatively small rates of about 2000 ppm. in the alkylation zone and about 3500 ppm. in the transalkylation zone. These two zones will be described more fully hereinafter. Generally, boron trifluoride is utilized as a pure vaporous material by direct passage to the reaction zones while dissolved in the aromatic feed stream. Although an organic solvent solution of BF₃ may be employed, such a technique is not preferred since BF₃ complexes with a multitude of organic compounds, and the latter can react with either the aromatic or olefinic feed material. Required quantities of BF₃ are relatively small, and may be conveniently expressed as grams of BF₃ per mole of olefin. The quantity of BF₃ used may be less than 1.0 gram per gram mole of olefin and preferably is from about 0.1 to 1.0 gram per gram mole.

The preferred boron halide-promoted alkylation process utilizes two reaction zones to produce mono-alkylated aromatic hydrocarbons. The first reaction zone is used to alkylate the aromatic hydrocarbon, which in the preferred embodiment results in the formation of ethylbenzene. The second reaction zone is used to transalkylate polyalkylated aromatics produced in the first reaction zone. According to the prior art methods of operating this process, the liquid phase portion of the effluent streams of the two reaction zones are combined and fed into a single fractional distillation column, referred to as the recycle benzene column. The alkylation reaction zone is normally operated in a downflow manner at a temperature of from 100° F. to 600° F., with the preferred operating temperature being from 250° F. to 450° F. The transalkylation reaction zone is normally operated in an upflow manner and maintained at a higher temperature of from 350° F. to 450° F., but may vary in temperature from about 200° F. to 700° F. The pressure in either reaction zone may range from about atmospheric to 1500 psig., although it is presently desirable to use a pressure range of from about 300 psig. to 600 psig. The pressure is preferably chosen to be sufficient to maintain the aromatic hydrocarbon compounds in a liquid state.

To obtain a high selectivity for the production of a mono-alkylated benzene in the alkylation zone, it is best to have present from about 1.5 to about 5 moles of benzene for each mole of ethylene. This is also true for the alkylation of other aromatic hydrocarbons and other olefins. The olefins are therefore to be completely reacted in the alkylation reaction zone and are not present in the effluent of this zone. The excess aromatic hydrocarbon also tends to reduce the polymerization of the olefin and acts as a heat sink. To maintain the high excess of aromatic material, it is common practice to recirculate a large amount of unfractionated reactor effluent, which may be up to about 15 times as large as the reactor feed stream or net reactor product. The liquid hourly space velocity used in the alkylation reaction zone may vary between 0.5 and about 10.0.

In the transalkylation zone, an excess of unalkylated aromatic hydrocarbons over polyalkylated aromatic hydrocarbons is maintained, with the relative ratio being from about 1.5 to about 3 moles of unalkylated aromatic hydrocarbon per mole of polyalkylated aromatic hydrocarbon. The liquid hourly space velocity of the reactants in the transalkylation reaction zone is preferably between about 0.2 to about 3. In order to obtain essentially complete conversion of polyethylbenzenes, the charge rate to the transalkylation reaction zone is generally more than three times that of the polyethylbenzene make. This is because the transalkylation reactions of polyethylbenzenes proceed at a much slower rate than the initial alkylation reaction of benzene. This greater charge rate may be obtained by the recycling of a portion of the transalkylation zone effluent stream. Operating conditions in either reaction zone may be varied to correspond to the type of alkylation step which is effected therein and to provide optimum yields. Further details on the preferred alkylation process may be obtained by reference to U.S. Pat. Nos. 2,887,520 and 3,631,122.

The preferred catalyst system is troubled by the formation of boron oxide hydrates in the alkylation zone by the reaction of small amounts of water contained in the feed stream with the boron trifluoride. If left untreated, these non-volatile compounds settle on the internal surfaces of the downstream benzene column and its associated reboiler. This decreases the efficiency of the column and would eventually require the operation of the process to be terminated to allow removal of these deposits. A preferred method of preventing the deposition of the boron oxide hydrates, commonly referred to as borates, in the benzene column is to form a volatile complex containing the borates by the addition of additional boron trifluoride to the bottom of the benzene column. The complex is concentrated by fractionation into a benzene recycle stream removed from the benzene column as a sidecut. The benzene recycle stream is then passed through a bed of activated alumina which selectively removes the complex. This is described in greater detail in U.S. Pat. No. 3,238,268. An alternative method in which an olefin-acting compound, such as ethylene or butylene, is passed into the bottom of the benzene column is described in U.S. Pat. No. 3,631,122.

The liquid phase portions of the reaction zones which remain at the reduced pressure of the low pressure separator are passed into a benzene column, which is operated under conditions effective to recover essentially all of the remaining benzene from the combined reaction zone effluent. This column is preferably operated with a bottom pressure of about 15 psig. and with about a 5 psig. pressure drop through the column. The liquid temperature at the bottom of the column will be maintained at about 350° F. to ensure complete removal of the benzene from the alkylated benzene being withdrawn as a bottoms liquid product. The temperature at the top of the column will be about 200° F. under these conditions. As used in this description, references to the benzene column are intended to refer generically to the fractionation column in which unreacted aromatic hydrocarbons are separated as a top product. This aromatic may be toluene, etc., but for convenience is assumed to be benzene.

The bottoms product of the benzene column is preferably passed into a second distillation column which is commonly referred to as an ethylbenzene column when ethylbenzene is being produced. Conditions suitable for operation of the second column include a pressure of about 10 psig. and a bottom temperature of about 425° F. An overhead vapor which is essentially pure ethylbenzene is removed as the net overhead product at a temperature of about 280° F. The design of these last two fractionation columns and their associated equipment, such as fractionation trays, is well within the expertise of those skilled in the art, and they may be of conventional design. The ethylbenzene column is located within the fractionation zone 42. This zone may contain only the ethylbenzene column and produce a bottoms stream of polyalkylated benzenes which are recycled to the transalkylation zone as in U.S. Pat. No. 3,126,421. Alternatively, the bottoms of the ethylbenzene column may be passed into a third fractionation column. Heavy polymers, etc., referred to as tar would be removed as the bottoms stream of this third column, and the polyalkylated benzenes would be removed as an overhead vapor stream. This fractionation system is shown in U.S. Pat. No. 2,995,611.

A net overhead gas stream is removed from the benzene column. This gas stream contains various light hydrocarbons, such as saturate C₂ to C₅ paraffins, which were dissolved in the liquids fed to the benzene column and also boron trifluoride dissolved in these liquids. It also will contain some boron trifluoride which was passed into the column as previously described to prevent borate deposition. This gas stream must be passed into a promoter recovery zone in which the boron trifluoride is recovered for reuse and to facilitate the discharge of the off-gas from the process. A suitable recovery zone configuration for use with the preferred catalyst system is shown in U.S. Pat. No. 3,126,421. The gas stream is passed upward through an absorption tower having about 12 trays countercurrent to a lean oil, and the boron trifluoride transfers into the lean oil. The resultant rich oil is then stripped to recover the boron trifluoride in a 24-tray stripping column. The lean oil may be polyalkylated benzenes such as are formed in the process. This lean oil preferably contains about 15-20% dimethoxybenzene (DMB). DMB forms a weak, thermally unstable complex on contact with the boron trifluoride and is easily recovered upon heating the lean oil in the stripper. The gases removed from the absorber column are passed through a caustic neutralization media to produce an environmentally acceptable effluent. Other types of equipment or different lean oils or additives may be used to recover other catalyst promoters.

The absorber in the promoter recovery zone is preferably operated at a higher pressure than is desired for use at the top of the benzene column. Therefore, the net off-gas of the benzene column which is to be passed into the promoter recovery zone, as well as that portion to be recycled to the reaction zone as in the prior art, must be compressed to be passed into the absorber. The additional compressor capacity required to do this increases both the capital cost and utility cost of the process. It is an objective of this invention to provide a process for the alkylation of aromatic hydrocarbons wherein a compressor is not necessary to pass the off-gas of the benzene column into a catalyst promoter recovery zone operating at a higher pressure than the benzene column.

According to the inventive concept at least a part of the motive force required to pass the net benzene column overhead gas into the promoter recovery zone is derived by depressurizing the vaporous phase of the alkylation zone effluent stream. This vaporous phase is comprised of the unreactive saturated paraffins contained in the olefin feed stream and boron trifluoride. In comparison, the effluent of the transalkylation zone will normally and preferably contain very little vapor, and therefore preferably is not used in the same manner as the alkylation zone effluent. As previously specified, the alkylation zone effluent preferably has a pressure ranging from about 300-600 psig. The pressure specified for the top of the benzene column was about 5 psig. There is therefore normally available a pressure differential of about 280 to 580 psig. between the low pressure stream to be pumped and the high pressure stream fed to the ejector. The ejector itself may be of customary design and can be chosen by those skilled in the art. Preferably, the outlet of the ejector will be at a pressure above about 50 psig. The relatively high pressure vapor-liquid separator in which the effluent of the alkylation zone is separated into vapor and liquid fractions may also be of customary design and is referred to herein as the high pressure separator or the first vapor-liquid separation zone. At least a portion of the vapor stream removed from this separation zone is used as the high pressure stream fed to the ejector. A second portion may be bypassed as desired to control the operation of the ejector.

The liquid stream removed from the first vapor-liquid separation zone preferably comprises most of the C₆ + hydrocarbons in the alkylation zone. It therefore contains the aromatic hydrocarbon and the product alkylaromatic hydrocarbon. It will also contain an equilibrium concentration of lower boiling hydrocarbons, such as ethane, and boron trifluoride and some polyalkylated aromatic hydrocarbons. Preferably, this liquid stream is admixed with the effluent of the translkylation zone and passed into a second vapor-liquid separation zone. Referring to the Drawing, this zone may be comprised only of the low pressure separator 15 or it may contain both the low pressure separator 15 and a third vapor-liquid separator 20. The second vapor-liquid separation zone is preferably operated at a pressure in the range of about 20-65 psig. Lower pressures may be used, but this pressure range allows the liquids to be transferred into the benzene column without the use of a pump. The pressure in this zone should also be greater than in the promoter recovery zone or its equivalent. Heat may be recovered from the reaction zone effluents through the use of a heat exchanger in line 14.

The vapor phase stream removed from the low pressure separtor 15 contains boron trifluoride and low boiling point hydrocarbons which are released from the entering liquid stream due to the lower pressure in the separator. It will also contain the boron trifluoride and light hydrocarbons contained in the effluent of the ejector and an equilibrium concentration of less volatile hydrocarbons such as the aromatic hydrocarbon. It is preferred that this vapor phase stream is cooled, as to about 100° F., and then passed into the third vapor-liquid separator. This has such advantages as allowing the low pressure separator 15 to be operated at a relatively warm temperature which produces a liquid phase effluent stream having a proper temperature for passage into the benzene column. Cooling the vapor phase effluent of the low pressure separator 15 produces a liquid phase containing the aromatic hydrocarbon. This valuable material is therefore not lost to the catalyst promoter recovery zone. The remaining uncondensed vapors are then passed into the promoter recovery zone. These vapors include boron trifluoride and light hydrocarbons removed from the top of the benzene column and which have been recycled without the use of a compressor, thereby achieving an objective of the invention.

In accordance with this description, the preferred embodiment of the invention may be characterized as a process for the alkylation of aromatic hydrocarbons which comprises the steps of passing a mixed phase reaction zone effluent stream which comprises a volatile catalyst promoter and two different aromatic hydrocarbons into a first vapor-liquid separation zone and forming therein a first liquid hydrocarbon stream comprising the aromatic hydrocarbons and a first vapor stream comprising the catalyst promoter; passing at least a portion of the first vapor stream through an ejector as a motive stream utilized to pump a second vapor stream comprising the catalyst promoter and thereby forming an ejector effluent vapor stream; passing the ejector effluent vapor stream into a second vapor-liquid separation zone having a lower pressure than the first vapor-liquid separation zone; passing the first liquid hydrocarbon stream into the second vapor-liquid separation zone; passing a second liquid hydrocarbon stream comprising the aromatic hydrocarbons and the catalyst promoter from the second vapor-liquid separation zone to a fractionation column having a lower pressure than the second vapor-liquid separation zone; withdrawing from the fractionation column a net overhead vapor stream comprising the catalyst promoter and passing the net overhead vapor stream into the ejector as the second vapor stream; withdrawing from the second vapor-liquid separation zone a third vapor stream comprising the catalyst promoter, and passing the third vapor stream into a vapor purification zone which effects the removal of imputities from the third vapor stream to produce a fourth vapor stream having a higher concentration of the catalyst promoter than the third vapor stream; passing at least a portion of the fourth vapor stream into a reaction zone maintained at alkylation promoting conditions in admixture with an olefinic hydrocarbon and a feed aromatic hydrocarbon; and withdrawing a fractionation product stream comprising a product alkylaromatic hydrocarbon from the fractionation column. As previously stated, the aromatic hydrocarbons in the reaction zone effluent will normally include the excess benzene or other feed aromatic hydrocarbon, the product aromatic hydrocarbon and any by-product aromatic hydrocarbons such as polyalkylated aromatics.

The configuration of the reactor and the conversion conditions which are maintained within the reactor may be chosen from the great variety which are customary for the specific process being performed. For example, the inventive concept may be applied to a hydroprocessing operation utilizing a fixed-bed reactor containing one or more beds of particulate catalyst. The reactor, or reaction zone if two or more reactors are utilized, may also be a moving-bed reactor. As used herein, the term "hydroprocessing" is intended to encompass three related fields of petroleum refining technology. The first is hydrotreating, wherein small amounts of undesirable materials including sulfur and nitrogen contained in various organic molecular structures are removed from the charge stock with very little molecular cracking. The second field is hydrocracking, wherein at least 50% of the charge stock is cracked into components having a lower molecular weight, such as the production of a naphtha from a heavy distillate or the production of LPG from a naphtha. The field of hydrorefining is between these two extremes and results in molecular changes to up to about 10% or more of the feed together with impurity removal.

The method of manufacture and the composition of the catalyst used in the reaction zone during the hydroprocessing operation is not critical. The catalyst may therefore be any suitable commercially-available catalyst or one of proprietary nature. These catalysts are normally formed as a sphere by an oil drop method, such as that demonstrated in U.S. Pat. No. 2,774,743, or extruded or pelleted. Basic to the manufacture of a large majority of all hydroprocessing catalysts is the incorporation of a metal of Group VIII of the Periodic Table on a refractory inorganic oxide carrier by coprecipitation or impregnation. The more commonly used metals from this group are iron, cobalt, nickel, platinum and palladium. In addition, metals from Group VI-A such as chromium, molybdenum or tungsten are also often incorporated into the catalyst. The carrier material may be natural or synthetic and will normally be selected from alumina, silica or zirconia or a combination of any of these materials, particularly an alumina in combination with one or more of the other oxides. A preferred catalyst composition is from 1-20 wt.% cobalt and from 0.1-10 wt.% molybdenum supported on alumina spheres. A more detailed listing of suitable catalyst composition and manufacturing techniques may be obtained by reference to U.S. Pat. Nos. 3,203,889; 3,254,018; 3,525,684 and 3,471,399.

The conversion conditions necessary for a hydroprocessing operation are determined by such factors as the composition of the charge stock, the catalyst used in the reactor and the desired result of the process. A broad range of hydroprocessing conditions includes a temperature of from about 250° F. to 1000° F., a pressure of from 300 to 4000 psig., and a liquid hourly space velocity of 0.1 to about 8.0. The exact reactor temperature required is determined by such factors as the initial activity and prior use of the catalyst. As a general rule, the preferred operating pressure will increase with the boiling point of the material being processed. More specific examples of hydroprocessing conditions are contained in the above-listed U.S. Patents. In all hydroprocessing operations, hydrogen is circulated through the reactor at a rate of about 500 to about 10,000 standard cubic feet per barrel of charge material.

An example of a hydroprocessing operation which may be conducted in the reaction zone of the subject invention is the hydrogenation of petroleum-derived feed streams containing polymer-forming olefinic materials. These olefinic materials may include olefins, conjugated di-olefins such as butadiene and styrene, and indenes. These compounds are often found in pyrolysis liquids, distillates from fluid cokers, coke oven light oils and coal gasification side-product liquids. Satisfactory conversion conditions for a low temperature hydrogenation reactor loaded with the preferred palladium-containing catalyst include a temperature in the broad range of from 250° F. to 500° F. Preferably, the reactor is operated at 270° F. to 400° F. On-stream hydrogenation conditions also include a pressure in the broad range of from 100 psig. to about 1200 psig. and a molar excess of hydrogen, typically in the range of from 500 to 2000 standard cubic feet per barrel of combined charge. The preferred catalyst comprises spheres of lithiated alumina containing from 0.05 wt.% to about 5.0 wt.% palladium. Preferably, the catalyst consists of 1/16-inch alumina spheres containing about 0.4 wt.% palladium and about 0.5 wt.% lithium. Further instruction as to the hydrogenation of olefinic feed streams may be obtained by reference to U.S. Pat. Nos. 3,161,586; 3,215,618; 3,537,981 and 3,537,982.

The inventive concept may also be used in the hydroprocessing of heavy petroleum stocks such as residual oils or black oils. These feed materials often have boiling points, as determined by the appropriate ASTM distillation procedure, above about 600° F. at 1 atmosphere of absolute pressure. They will normally contain appreciable amounts of asphaltenes, sulfur and various metals, such as iron, nickel and vanadium. The fluid stream passed through the reaction zone may therefore be formed by the admixture of hydrogen and the various petroleum streams, such as an atmospheric tower bottoms, a vacuum tower bottoms (vacuum residuum), a topped crude oils, a coal oil extract, or a shale oil or heavy oil recovered from tar sands.

In a great majority of all hydroprocessing operations, the effluent of the reaction zone is separated for the recovery of the valuable hydrogen which it may contain from the products and by-products of the process. Typically, the effluent of the reaction zone will be cooled to effect at least a partial condensation of the heavier hydrocarbons and then passed into a vapor-liquid separation zone. Liquid hydrocarbon streams formed in this manner are then often passed into a fractionation column wherein the hydrocarbons are purified or separated. The fractionation column which receives the liquid hydrocarbons may be referred to as a stripper, stabilizer, debutanizer, deethanizer, etc. The hydrocarbon stream fed to the fractionation column will contain the heavier, more readily condensible hydrocarbons and also various amounts of dissolved lighter hydrocarbons or condensed gases. One function of this fractionation column will be to remove some or all of the low boiling hydrocarbons and dissolved gases from the feed stream and thereby form streams of differing composition which may be removed as sidecuts or bottoms steams from the column. Although these light materials may be considered impurties when present in the heavier hydrocarbon streams removed from the fractionation column, they may have a large economic value which justifies their recovery and separation. For this reason, these streams are often passed into a purification or recovery zone which may have several different forms.

The net vapor stream removed from the fractionation column may be passed into an absorption zone via the second vapor-liquid separation zone in accordance with the inventive concept. This absorption zone may be operated in a manner similar to those used in the gas concentration unit associated with many fluidized catalytic cracking units. The vapor stream which is withdrawn from the second vapor-liquid separation zone may accordingly be passed into the bottom of a cylindrical multi-stage absorption column wherein it passes upward countercurrent to a descending stream of naphtha, gas oil or other suitable absorption liquid. Preferably, the absorption zone comprises a vertically-disposed trayed absorption tower having a total of twenty or more contact stages. The absorption zone is maintained at conditions selected to cause the absorption of at least a portion of components of the vapor steam which it is desired to recover. In general, for hydrocarbons, these conditions include a pressure of from about 100 to 500 psig. or higher and a temperature of from about 60° F. to 150° F. A preferred temperature range for the effluent streams from the absorption zone is 80° F. to 140° F. The relatively elevated pressure maintained within the absorption zone facilitates the absorption and recovery of such hydrocarbons as ethane, propane, butane and pentane. These hydrocarbons become components of a rich liquid stream which is removed from the bottom of the absorption column and transferred to a stripping column wherein, at conditions of a greater temperature and/or lesser pressure, they are recovered. The separation and recovery of light hydrocarbons from a gas stream in this manner is well known and is described in greater detail in U.S. Pat. Nos. 3,907,669; 4,009,097 and 4,010,010.

The net gas stream removed from the second vapor-liquid separation zone during the hydroprocessing of a sulfur-containing feed stream may be subjected to a purification operation designed to remove hydrogen sulfide or other acidic gases either before or subsequent to its passage into an absorption zone. As an alternative, the acid gases may be removed and the resultant purified gas stream recycled directly to the reaction zone. This acid gas removal operation may comprise contacting with an aqueous caustic solution in the customary manner well known to those skilled in the art. The removal of acid gases and light hydrocarbons from the gas stream withdrawn from a second vapor-liquid separation zone will normally effect the production of a vapor stream having a sufficiently high hydrogen concentration for use as a recycle gas in the hydroprocessing reaction zone.

The inventive concept may also find application in a process for the hydrodealkylation of alkylaromatic hydrocarbons. A process for the thermal dealkylation of toluene is presented in U.S. Pat. Nos. 3,284,526 and 3,291,849. The reaction zone may also contain a catalyst as described in U.S. Pat. Nos. 3,751,503 and 3,291,850. These processes typically utilize a hydrogen-rich recycle stream which is derived from the reaction zone effluent. The liquid phase portion of the reaction zone effluent is passed into a fractionation column to separate the product benzene from unconverted toluene which is to be recycled to the reaction zone and to remove light hydrocarbons such as ethane or propane, which are the result of cracking reactions which occur in the reaction zone, from the product stream. It is undesirable to pass significant quantities of light paraffinic hydrocarbons to the reaction zone. For this reason, gas steams which are to be passed into the reaction zone have been contacted with a lean oil in an absorption zone under conditions which remove the paraffinic hydrocarbons and purify the hydrogen-containing gas stream. The subject invention may be adapted to this hydrodealkylation process by utilizing it to pass a recycle gas stream comprising vapors from the fractionation column into a similar purification zone.

The fractionation column utlized in the subject invention is preferably a trayed column containing twenty or more trays and operated at a pressure less than 100 psig. This pressure is to be measured at the top of the fractionation column. The column is preferably operated at a reflux to feed ratio of from 0.5 to about 3.0, and the liquid feed stream from the second vapor-liquid separation zone may enter at either the top or an intermediate point of the fractionation column. As used herein, the term "net overhead vapor stream" or its equivalent is intended to refer to the vapor stream removed from the overhead system of a fractionation column after the condensation of hydrocarbons used as reflux liquid and/or an overhead liquid product. Two or more columns may be utilized as an integrated fractionation zone associated with the specific conversion process being performed. 

I claim as my invention:
 1. A hydrocarbon conversion process which comprises the steps of:(a) reacting hydrocarbons of said hydrocarbon conversion process in a reaction zone to form a mixed-phase reaction zone effluent stream comprising a hydrocarbon having six or more carbon atoms per molecule and at least one volatile chemical consisting essentially of a catalyst promoter selected from the group consisting of boron trifluoride, carbon tetrachloride, hydrogen fluoride, and hydrogen bromide; (b) passing said mixed-phase reaction zone effluent into a first vapor-liquid separation zone to therein separate said mixed-phase effluent to a first liquid hydrocarbon stream comprising a hydrocarbon having six or more carbon atoms per molecule and a first vapor stream comprising a catalyst promoter consisting essentially of at least one volatile chemical selected from the group consisting of boron trifluoride, carbon tetrachloride, hydrogen fluoride, and hydrogen bromide; (c) passing at least a portion of said first vapor stream through an ejector as a motive stream utilized to pump a second vapor stream comprising catalyst promotor consisting essentially of at least one volatile chemical selected from the group consisting of boron trifluoride, carbon tetrachloride, hydrogen fluoride, and hydrogen bromide to form an ejector effluent vapor stream; (d) passing said ejector effluent vapor stream into a second vapor-liquid separation zone having a lower pressure than said first vapor-liquid separation zone; (e) passing said first liquid hydrocarbon stream into said second vapor-liquid separation zone; (f) passing a second liquid hydrocarbon stream comprising said hydrocarbon having six or more carbon atoms per molecule from said second vapor-liquid separation zone to a fractionation zone having a lower pressure than said second vapor-liquid separation zone; (g) withdrawing from said fractionation zone a net overhead vapor stream comprising the catalyst promotor consisting essentially of a volatile chemical selected from the group consisting of boron trifluoride, carbon tetrachloride, hydrogen fluoride, and hydrogen bromide, and passing said net overhead vapor steam into said ejector as the second vapor stream; (h) withdrawing from said second vapor-liquid separation zone a third vapor stream comprising the catalyst promotor consisting essentially of a volatile chemical selected from the group consisting of boron trifluoride, carbon tetrachloride, hydrogen fluoride, and hydrogen bromide, and passing said third vapor stream into a vapor purification zone to effect removal of an impurity from said third vapor stream to produce a fourth vapor stream having a higher concentration of said volatile chemical than possessed by said third vapor stream; and (i) withdrawing a fractionation product stream comprising said hydrocarbon having six or more carbon atoms per molecule from said fractionation zone.
 2. The process of claim 1 further characterized in that at least a portion of said fourth vapor stream is passed into said reaction zone of step (a).
 3. The process of claim 1 further characterized in that a normal paraffin having over three carbon atoms per molecule is removed from said third vapor stream in said vapor purification zone as said impurity.
 4. A process for the alkylation of an aromatic hydrocarbon which comprises the steps of:(a) alkylating an aromatic hydrocarbon with an olefinic hydrocarbon in the presence of a volatile catalyst promoter in an alkylation reaction zone to form a mixed-phase alkylation zone effluent which comprises said volatile catalyst promoter and at least two different aromatic hydrocarbons; (b) passing said mixed-phase alkylation zone effluent stream which comprises said volatile catalyst promoter and said two different aromatic hydrocarbons into a first vapor-liquid separation zone to form therein a first liquid hydrocarbon stream comprising said aromatic hydrocarbons and a first vapor stream comprising said catalyst promoter; (c) passing at least a portion of said first vapor stream through an ejector as a motive stream utilized to pump a second vapor stream comprising the catalyst promoter to form an ejector effluent vapor stream; (d) passing said ejector effluent vapor steam into a second vapor-liquid separation zone having a lower pressure than said first vapor-liquid separation zone; (e) passing said first liquid hydrocarbon stream into said second vapor-liquid separation zone; (f) passing a second liquid hydrocarbon stream comprising said aromatic hydrocarbons and said catalyst promoter from said second vapor-liquid separation zone to a fractionation column having a lower pressure than said second vapor-liquid separation zone; (g) withdrawing from said fractionation column a net overhead vapor steam comprising said catalyst promoter and passing said net overhead vapor stream into said ejector as said second vapor stream; (h) withdrawing from said second vapor-liquid separation zone a third vapor stream comprising said catalyst promoter, and passing said third vapor stream into a vapor purification zone which effects the removal of impurities from said third vapor stream to produce a fourth vapor stream having a higher concentration of said catalyst promoter than said third vapor stream;(i) passing at least a portion of said fourth vapor stream into said alkylation reaction zone maintained at alkylation-promoting conditions in admixture with said olefinic hydrocarbon and said aromatic hydrocarbon feed; and, (j) withdrawing a fractionation product stream comprising a product alkylaromatic hydrocarbon from said fractionation column.
 5. The process of claim 4 further characterized in that said catalyst promoter is selected from the group consisting of boron trifluoride, boron trichloride, boron tribromide, hydrogen chloride, carbon tetrachloride, hydrogen fluoride, hydrogen bromide, ammonium fluoride, ammonium chloride, ammonium bromide and ammonium iodide. 